Alternatives to Amira Software

AnalyzeDirect is a company focused on medical technology research that excels in distributing and supporting Analyze, a premier software for advanced biomedical imaging visualization, manipulation, and measurement across the globe. The latest version, Analyze 15.0, provides an easy-to-use interface for image visualization and analysis tailored for medical research, equipped with advanced segmentation tools that allow for rapid and accurate definition of regions, extensive statistical analysis capabilities with reliable measurement tools, and powerful registration features for fusing images from different modalities. It also includes a diverse set of display options for thorough image review and visualization, along with filtering tools that enhance post-processing and optimization of images. This software is compatible with over 45 different file formats, such as DICOM as well as various standard radiological and neurological formats. Its user base spans physicians, scientists, professors, and graduate students at leading medical institutions, universities, pharmaceutical firms, biotech organizations, medical device manufacturers, and contract research entities around the world. AnalyzeDirect continues to innovate in this field, ensuring that users have access to the most effective and cutting-edge tools for their research needs.

3D-DOCTOR is a sophisticated software solution designed for 3D modeling, image processing, and measurement across various imaging modalities, including MRI, CT, PET, and microscopy, as well as scientific and industrial applications. It accommodates both grayscale and color images in multiple formats such as DICOM, TIFF, Interfile, GIF, JPEG, PNG, BMP, PGM, MRC, RAW, and more. This powerful software generates 3D surface models and performs volume rendering from 2D cross-sectional images in real-time on your computer. Users can export polygonal mesh models in various formats, including STL, DXF, IGES, 3DS, OBJ, VRML, PLY, and XYZ, making it suitable for applications like surgical planning, simulation, quantitative analysis, finite element analysis, and rapid prototyping. In addition, it allows for 3D volume calculations and other measurements crucial for quantitative insights. The vector-based tools enhance the ease of handling image data, facilitating measurement and analysis efficiently. Moreover, 3D CT and MRI images can be re-sliced along any chosen axis, and it is capable of registering multi-modality images to produce comprehensive image fusions, ensuring a versatile approach to imaging challenges.

Vesalius3D is an advanced software solution designed for exceptional 3D visualization and exploration of personalized anatomical structures specific to individual patients. This tool enables users to visualize intricate details of patient anatomy that may be overlooked when relying solely on traditional 2D imaging slices. With its user-friendly interface, the software allows for quick navigation within the patient’s anatomy, providing a seamless experience. Importantly, Vesalius3D operates with standard medical imaging modalities like CT, MRI, and Ultrasound, eliminating the need for specialized scans. It includes presets tailored to the most frequently encountered tissue types. Additionally, the software features preconfigured visualizations that let users immediately access results without the hassle of manual adjustments, focusing on commonly used tissues. Beyond visualization, Vesalius3D includes an array of measurement tools, offering both 2D quantification options—such as measuring distances, angles, and contour areas—and 3D quantification capabilities to analyze shapes, contours, and spatial relationships accurately. This comprehensive suite of features empowers healthcare professionals to gain deeper insights into patient anatomy efficiently.

3D Slicer is an open-source software tool that provides a comprehensive platform for visualizing, processing, segmenting, registering, and analyzing medical and biomedical 3D images and meshes. In addition to these features, it supports the planning and navigation of image-guided medical procedures. Functioning as a desktop application, 3D Slicer tackles complex challenges in image computing, specifically tailored for clinical and biomedical contexts. Furthermore, it acts as a development framework that allows for the swift creation and implementation of custom applications for both research and commercial endeavors. The platform is backed by a vibrant community of skilled users and developers who work together to enhance the field of medical computing. Distributed under a BSD-style license, 3D Slicer places no limitations on its use in both academic and commercial settings, but it is important to note that the software is not FDA-approved, placing the onus on users to ensure they meet relevant regulatory requirements. This collaborative environment fosters innovation and encourages the development of unique solutions to meet the evolving needs of the medical field.

EMSE is a comprehensive suite of sophisticated and user-friendly software tools designed for measuring, describing, and visualizing the dynamics of the human brain, utilized globally in fields such as neuroscience, neurotechnology, and clinical neurophysiology. Our expertise lies in advanced multimodal source estimation techniques, which empower researchers to integrate EEG and MRI datasets, thus providing clearer insights into both the spatial and temporal aspects of brain activity. Traditional neuroimaging methods, like magnetic resonance imaging (MRI), excel in locating brain activity but fall short in determining the timing of events. In contrast, electroencephalography (EEG) and its related technique, Event-Related Potentials (ERPs), can pinpoint when neural events occur with remarkable precision, but they struggle with spatial localization. By merging MRI and EEG data, EMSE uniquely addresses both the "where" and "when" questions of brain activity, offering a level of detail that neither technique can achieve on its own. This innovative approach is referred to as multimodal dynamic functional brain imaging or source estimation, allowing for a deeper understanding of the brain's intricate workings. By leveraging this technology, researchers can uncover new insights into brain dynamics that were previously unattainable.

Harness the capabilities of Simpleware software to effortlessly handle 3D and 4D imaging data sourced from MRI, CT, and micro-CT scans. Explore your data through sophisticated visualization techniques, thorough analysis, and precise quantification methods. Develop accurate models that are primed for design, simulation, and 3D printing processes. The latest Simpleware W-2024.12 update enhances the software's integration of AI-driven segmentation tools and optimized design functionalities, significantly speeding up your 3D image processing and analytical workflows. Our cutting-edge platform for 3D image processing and model creation enables the transformation of 3D and 4D image data into products and workflows that integrate effortlessly with design and simulation applications. With a user-friendly interface, you can quickly access all necessary tools and features. Conduct extensive analyses of even the most intricate 3D image datasets, ensuring the generation of top-tier design and simulation-ready models that meet your exacting standards. This advancement allows users to leverage the latest technology for better results in their projects.

Vitrea software serves as a versatile and vendor-neutral advanced visualization platform that delivers a wide range of applications across various IT settings, whether in single-site or multi-site configurations. With Vitrea Advanced Visualization, organizations can achieve standardization and streamline their radiology IT landscape effectively. The use of Global Illumination, a sophisticated 3D rendering method, enhances the photorealism of anatomical images. This allows users to capture and disseminate these visualizations for educational and communication purposes. Moreover, advanced imaging features, including in-suite 3D visualization and semi-automated measurement tools, empower healthcare providers to access patient data conveniently from any location. Furthermore, radiologists have the capability to share imaging results seamlessly throughout their entire organization. This interconnected approach not only improves collaboration but also enhances the overall quality of patient care.

Caas MR 4D Flow is expertly crafted to efficiently extract pertinent data from 3D phase-contrast MR images with minimal effort. Utilizing these advanced images, it provides two innovative 4D Flow modules that facilitate comprehensive flow analysis, which is instrumental in the assessment and interpretation of cardiovascular MR images, as well as in strategizing the timing and nature of interventions. One of these modules focuses on evaluating blood vessels, ranging from major arteries like the aorta to smaller vessels such as those found in the kidneys, while the other specializes in assessing heart valves concerning regurgitation fraction. Among the significant outputs are the visualization of aortic blood flow presented as streamlines, pathlines, and color-coded vectors; detailed mapping of wall shear stress alongside localized wall shear stress values; measurement of pressure differences across specific segments; and the visualization and quantification of regurgitant fractions for all four heart valves, in addition to conducting 2D flow phase-contrast analyses. This comprehensive approach not only enhances understanding but also significantly aids clinicians in making informed decisions regarding patient care.

Qure.ai's qLC-Suite is a cutting-edge AI-driven tool aimed at improving the early identification and management of lung nodules, which is crucial for prompt lung cancer intervention. This solution delivers accurate measurements, thorough characterization, and 3D imaging of lung nodules, ensuring that opportunities for early treatment are not overlooked. It is capable of supporting both incidental and targeted screenings by efficiently identifying nodules and calculating their volume with just one click. Moreover, the system monitors volumetric changes over time, providing valuable insights into nodule development. The qLC-Suite is designed to integrate smoothly into current workflows, offering quick analysis and reporting that assist healthcare professionals in their decision-making processes. In addition to its analytical capabilities, it serves as a comprehensive platform for managing lung nodules, facilitating care coordination through intelligent prompts, providing hardware-agnostic image viewing for AI-enhanced chest X-rays and CT scans, enabling seamless sharing of scans across departments, and allowing for tailored notifications for cases of concern. Overall, qLC-Suite represents a significant advancement in lung cancer care, promoting timely interventions that can ultimately save lives.

Dragonfly 3D World, developed by Object Research Systems (ORS), serves as a sophisticated software platform tailored for the visualization, analysis, and collaborative study of multidimensional images across various scientific and industrial domains. This platform boasts an array of robust features that facilitate the visualization, processing, and interpretation of 2D, 3D, and even 4D imaging data, which can be obtained from modalities like CT, MRI, and electron microscopy, among others. Users can engage in interactive exploration of intricate structures through real-time volume rendering, surface rendering, and orthogonal slicing capabilities. The integration of artificial intelligence within Dragonfly empowers users to harness deep learning techniques for tasks such as image segmentation, classification, and object detection, significantly enhancing analytical precision. Additionally, the software includes sophisticated quantitative analysis tools that allow for region-of-interest investigations, measurements, and statistical assessments. The user-friendly graphical interface of Dragonfly ensures that researchers can construct reproducible workflows and efficiently conduct batch processing, promoting consistency and productivity in their work. Ultimately, Dragonfly 3D World stands out as a vital resource for those seeking to push the boundaries of imaging analysis in their respective fields.

ActiViz is a comprehensive 3D visualization library tailored for .NET C# and Unity, facilitating the seamless incorporation of sophisticated 3D visualization capabilities into applications. It is founded on the open-source Visualization Toolkit (VTK) and encompasses a diverse range of visualization algorithms, which include scalar, vector, tensor, texture, and volumetric techniques. Moreover, ActiViz boasts advanced modeling functionalities such as implicit modeling, polygon reduction, mesh smoothing, cutting, contouring, and Delaunay triangulation, enhancing its versatility in various applications. This library enables developers to quickly create interactive 3D applications ready for production within the .NET ecosystem, with additional support for Windows Presentation Foundation (WPF). Furthermore, its compatibility with Unity software broadens its potential uses, making it suitable for both game development and interactive simulations. Notably, the latest version, ActiViz 9.4, introduces support for multiple .NET versions from .NET Framework 4.0 to .NET 8, along with innovative features like curved planar reformation for generating panoramic views, highlighting its continuous evolution and adaptability in the field.

OsiriX is a highly esteemed medical imaging software designed for viewing DICOM (Digital Imaging and Communications in Medicine) files, catering especially to healthcare professionals who require efficient management and analysis of medical images. This versatile platform boasts capabilities for 2D, 3D, and 4D visualization, complemented by sophisticated post-processing tools that enhance diagnostic precision. Its advanced features, including volume rendering and detailed image manipulation, make it a preferred choice among radiologists, clinicians, and researchers worldwide. Available in two versions, OsiriX provides a free (Lite) option alongside a paid (MD) version that includes enhanced functionalities and necessary certifications for clinical application, such as FDA and CE approvals. Additionally, the software's user-friendly interface and robust performance contribute to its widespread adoption in the medical community.

Axial3D is committed to enhancing personalized healthcare by revolutionizing the industry with its innovative 3D medical imaging and tailored patient solutions, thereby making individualized surgical care both routine and scalable. Their proprietary AI-driven platform, which operates in the cloud, enables medical device manufacturers, imaging specialists, and healthcare facilities to utilize rich data for creating precise 3D models that facilitate better surgical planning, lead to improved patient outcomes, and streamline workflows. Among the offerings are 3D visualizations, mesh files, print-ready files, and actual 3D printed models, all crafted to seamlessly fit into current medical practices. By transforming intricate DICOM images into accurate, actionable 3D representations, the company significantly enhances efficiency, speed, and scalability in the development of patient-specific devices. The cloud-based platform uniquely equips surgeons with a detailed perspective of their patient’s anatomy before surgery, thereby improving the accuracy and precision of surgical planning far beyond what traditional 2D imaging can provide. This advancement not only benefits individual patients but also paves the way for broader applications in the medical field.

Materialise Mimics is an all-encompassing software solution aimed at transforming medical imaging data into precise 3D models, serving a variety of purposes such as custom device development and detailed anatomical studies. This platform includes a diverse array of tools that streamline the planning, designing, and 3D printing processes for models and surgical guides tailored to different levels of complexity, enabling immediate use in clinical settings. Central to the platform is Mimics Core, a sophisticated software designed for 3D medical image segmentation that efficiently transitions from image capture to the creation of 3D models. This functionality aids in virtual procedure planning and is essential to the overall effectiveness of the platform. Additionally, the Mimics Innovation Suite expands the platform's capabilities by offering advanced resources for engineers and researchers. By simplifying the engagement with 3D medical imaging data, it becomes a valuable asset for improving patient outcomes through innovative technological applications. Ultimately, this software provides a crucial bridge between advanced imaging techniques and practical medical solutions.

The Medical Imaging Suite from Google Cloud is crafted to revolutionize the way organizations handle imaging diagnostics by ensuring that imaging data is not only accessible but also interoperable and beneficial. This suite provides a secure, compliant, and fully managed service to oversee healthcare data in various formats such as FHIR, HL7v2, and DICOM, alongside unstructured text in natural language. Utilizing a cloud infrastructure simplifies the process of storing and sharing extensive collections of medical images that are prevalent in the healthcare sector, making it both efficient and economical. The Cloud Healthcare API facilitates operations to read DICOM instances, studies, and series in alignment with the DICOMweb standard. Furthermore, the suite enhances research capabilities and improves the overall patient experience in healthcare by providing comprehensive solutions for data storage and analysis, among other functionalities. Additionally, it offers guidance on concepts and best practices for the integration of third-party medical imaging viewers with the Cloud Healthcare API, ensuring a seamless experience for users. This holistic approach not only streamlines workflow but also fosters innovation in the medical imaging landscape.

Implement comprehensive clinical decision support across your entire organization. Enhance your PACS and EMR systems to streamline imaging processes and boost patient care quality. We recognize that you manage diverse types of images from various sources, and your patients deserve optimal care. While sometimes a single solution may suffice, achieving an enterprise-wide AI-powered imaging analysis is possible with a contemporary technology framework and an intuitive user interface tailored for all physicians. Whether it's for radiology assessments, procedural planning, or consultations at the point of care, users can utilize a complete range of clinical resources through a robust advanced UI or a straightforward web-based interface. TeraRecon is capable of handling multiple imaging modalities and can support up to 40 concurrent users engaged in sophisticated image processing from one virtual server, whereas competitors typically struggle to accommodate many modalities or users without requiring additional servers. This scalability and flexibility position TeraRecon as a leader in the field of imaging solutions.

Brainlab's Elements Multiple Brain Metastases SRS represents a cutting-edge software solution aimed at optimizing the planning and execution of treatment for patients suffering from multiple brain metastases. This innovative workflow allows healthcare providers to target several metastases at once without subjecting the entire brain to radiation, thus significantly shortening the duration of treatment delivery. The procedure starts with pre-planning steps that are supported by automation, which includes tasks like image fusion, distortion correction, object outlining, and segmentation; all of which enhance both the speed and precision of the planning process. The software utilizes inverse-optimized dynamic conformal arc techniques, focusing on a single isocenter to achieve highly conformal dose distributions with sharp gradients, ensuring accurate target coverage while protecting surrounding healthy tissue. This method facilitates the rapid generation of consistent, high-quality radiosurgery plans within minutes, ultimately benefiting clinicians and patients alike by reducing treatment durations and enhancing overall outcomes. Moreover, the efficiency and effectiveness of this software can lead to improved patient satisfaction and a more streamlined clinical workflow.

HeartFlow offers a groundbreaking, non-invasive cardiac test that delivers detailed visualizations of individual coronary arteries, allowing doctors to develop more tailored treatment strategies for their patients. The process begins when a patient has a standard coronary computed tomography scan performed at a medical facility. Following this scan, the CT images are securely sent to our cloud-based system. Utilizing cutting-edge algorithms powered by artificial intelligence, we create a customized digital representation of the patient's coronary arteries. Our skilled analysts then review this model, making necessary adjustments to ensure accuracy. After finalizing the patient-specific model, the HeartFlow pathway employs physiological principles and computational fluid dynamics to analyze blood flow and compute FFRCT values throughout the model. We adhere to strict and well-established protocols throughout this entire process, ensuring uniform processing for every individual patient, which ultimately enhances the quality of care provided. This innovative approach not only improves diagnostic precision but also empowers healthcare providers to make informed decisions for optimal patient outcomes.

CubeVue software by CurveBeam AI offers an array of robust visualization features that significantly improve dataset analysis, providing users with intuitive tools for interpretation and treatment planning right at their fingertips. Among the basic visualization functionalities are options for zooming, panning, adjusting window levels, measuring distances and angles, saving case workups, comparing studies side by side, and exporting images in DICOM or JPEG formats, including 3D views. More advanced features include dynamic 3D renderings, multiplanar reconstruction (MPR) views, and SimX views. The dynamic 3D renderings provide the flexibility to rotate and visualize the volume from any perspective, allowing users to peel away layers of skin for clinical evaluation and scroll through the volume slice by slice. MPR views facilitate the on-the-fly rotation of planes, enabling users to create custom reformats instantly, synchronize navigation across coronal, axial, and sagittal slices, and modify slice thickness for tailored slabs. Additionally, SimX views produce digitally reconstructed radiographs derived from CT data, enhancing diagnostic capabilities and contributing to better patient outcomes. This comprehensive suite of visualization tools empowers healthcare professionals to make informed decisions during the treatment planning process.

XDR’s Dental Imaging Software is expertly designed to provide both user-friendly functionality and exceptional diagnostic capability. It features an Exposure Meter that enhances both the capturing and diagnosing processes. Users can effortlessly apply filters such as the Perio, Sharp, and Endo with just a single click. It also allows for cumulative measurements and real-time image viewing during charting, thanks to its Floater feature. The software incorporates a patented Unwarp technology to correct projective distortion, along with Bi-Directional Scaling for precise rescaling. Additionally, it offers a virtual acetate overlay designed specifically for implant planning and supports preformatted text insertion for efficiency. Users can easily select tooth numbers and utilize a misfiled exams finder. This robust software can detect even the faintest lesions and the narrowest files. It consistently ranks among the best in peer-reviewed studies, providing exposure feedback to ensure diagnostic accuracy while adhering to ALARA principles. By leveraging advanced mathematics and radiographic physics, this software stands out as a powerful tool in dental imaging. Ultimately, it enhances the overall workflow and accuracy of dental diagnostics.

ActivityBase stands out as the premier software platform in the industry for managing screening data, offering an array of sophisticated data analysis tools along with integrated object and compound registration features, making it the go-to database for researchers. This versatile system supports a diverse array of biochemical, cellular, and biophysical assay formats—such as Ion Channel, FLIPR, Kinetic, SPR, and Mass Spectrometry assays—ensuring comprehensive analytical capability. Additionally, it seamlessly connects with HCS imaging storage solutions like Perkin Elmer Columbus, Thermo Fisher HCS Studio, and Molecular Devices MDCStore, facilitating straightforward data and image imports. Moreover, ActivityBase includes essential tools for compound registration and plate management, enhancing usability for researchers. By utilizing ActivityBase, you can efficiently monitor and manage assay results accumulated over the years within a single, centralized system. The platform is adaptable to your specific requirements, eliminating the need for purchasing additional analysis packages, and through optimized data analysis processes, it has the potential to significantly boost your laboratory's analytical efficiency. In summary, ActivityBase not only streamlines data management but also empowers researchers to maximize their workflow and productivity.

Brainlab's Elements Spine Stereotactic Radiosurgery (SRS) represents a cutting-edge software solution aimed at refining the management of spinal metastases. This innovative workflow features automation at each phase, encompassing anatomical mapping, curvature adjustments, and target identification, which guarantees precision and uniformity down to submillimetric levels. A distinctive algorithm addresses variations in spinal curvature, thereby improving the accuracy of image fusion. The software employs automatic segmentation of spinal anatomy through a patented synthetic tissue model that effectively identifies and labels different spine levels for accurate dose calculations. Tools for outlining spinal tumors are included for Gross Tumor Volume (GTV) contouring, along with automatic suggestions for the Clinical Target Volume (CTV) and a cropped spinal canal object in alignment with International Spine Consortium Guidelines. Furthermore, the integration of AI-driven contouring solutions allows for the swift and dependable delineation of over 200 structures, including lymph nodes. This advancement not only streamlines the treatment process but also enhances overall patient outcomes in spinal cancer management.

Studycast is a cloud-based PACS and imaging workflow platform that helps providers work faster and more securely. Clinicians can access diagnostic-quality images, document findings, and create structured reports from any location. Its intuitive design streamlines the entire process from exam to archive, improving efficiency, reducing costs, and supporting quicker patient care. As a true cloud-native system, Studycast requires no complex installations or expensive hardware. It provides secure access from any internet-connected device and unifies the full imaging workflow within one simple platform. The workflow is fully end-to-end: orders route directly to imaging equipment, studies upload automatically to the cloud, and technologists complete before sending cases to physicians. Automatic alerts notify clinicians when studies are ready, reducing delays. Physicians can review cine loops, compare images, annotate diagrams, take measurements, and sign reports digitally from any location. More than 120 specialized worksheets (including echo, OB, POCUS, vet, and more) support accuracy and consistency, featuring auto-filled measurements, dropdown fields, and interactive diagrams. Studycast Advisor™ provides guideline-based recommendations to enhance reporting. Providers can log in from desktops, laptops, or mobile devices with secure access to studies and reports. Results can be shared easily with patients and referring providers through HIPAA- and PIPEDA-compliant portals. All data is encrypted and stored across multiple secure sites for redundancy and long-term compliance. Automated archiving ensures information stays protected and accessible. Studycast can be implemented in just a few weeks, with configuration support, unlimited training, and ongoing assistance included.

Fovia's XStream HDVR SDK Suite delivers an extensive array of tools for sophisticated visualization, allowing for effortless integration across multiple platforms, such as enterprise networks, independent workstations, and cloud-enabled mobile applications. Within this suite, users will find features like F.A.S.T. Interactive Segmentation, which supports dynamic 3D segmentation, F.A.S.T. RapidPrint for efficient volume-to-print processes, and F.A.S.T. Cloud SDK designed for advanced visualization in the cloud. These innovative tools empower the creation of tailored workflows and high-performance imaging applications that enhance user experience. Furthermore, Fovia offers a user-friendly API coupled with custom integration support, ensuring that a wide range of needs in the advanced visualization sector are effectively addressed. This commitment to versatility and user satisfaction solidifies Fovia's position as a leader in the visualization technology market.

Slice:Drop is an interactive online platform designed for viewing medical imaging data in three dimensions, enabling users to swiftly examine scientific and medical imagery. It seamlessly accommodates various scientific file formats, including volumetric data, models, and fibers right from the start. Users can effortlessly drag and drop their medical imaging files onto the site, eliminating the need for any file conversions, allowing for immediate rendering. The platform utilizes WebGL and HTML5 canvas technology to visualize data in both 2D and 3D while employing its proprietary open-source toolkit known as XTK. Importantly, all data processing occurs on the client side, which means no information is transmitted over the internet, thereby safeguarding privacy and security. Furthermore, Slice:Drop provides a range of functionalities, such as adjusting 3D opacity, configuring window/level settings, implementing thresholding, and controlling label map opacity for volumetric data; as well as managing show/hide options, opacity settings, and scalars for mesh data; and applying show/hide features and fiber length thresholds for fiber visuals. This makes it an invaluable resource for professionals in the medical field who require efficient and secure access to imaging data.

INFINITY ANALYZE 7 is a user-friendly software solution tailored for camera management, capturing images, and processing them in life science, clinical, and industrial research settings. It accommodates both brightfield and fluorescence imaging modes, guaranteeing results that are reproducible, precise, and of high quality. The software boasts a variety of functions, including image processing, fluorescence acquisition, calibration settings, customizable presets, annotations, and extensive camera controls. Users are able to engage in activities such as focus stacking, image stitching, and executing numerous post-processing techniques on the acquired images. The fluorescence functionality supports both multi-channel and single-channel image acquisition, simplifying the creation of composite images from sequences. Enhanced workflow efficiency is achieved through user-defined button labels and hotkeys, which provide rapid access to presets during microscope objective switches. Additionally, users can incorporate annotations such as lines, arrows, and shapes to emphasize specific areas of interest within their images, further enriching the visual data presentation. This versatility makes INFINITY ANALYZE 7 an invaluable tool for researchers aiming for detailed and organized imaging capabilities.

Zegami makes it easier to deliver explainable imaging AI more quickly and accurately. Zegami's full-stack service allows researchers, data scientists, and medical professionals to deliver explainable AI with greater efficiency. Our team and tools are your data science plug-in to create, validate, and enhance machine learning models in healthcare, life science, and manufacturing to propel your business or project forward.

Dragonfly is a robust, adaptable, and easy-to-use software that provides quantitative solutions for a wide range of imaging studies, such as 2D, 3D, and 4D analyses, effectively handling data from various imaging systems like correlative and hyperspectral imaging, X-ray, SEM, FIB-SEM, ion beam, and confocal microscopy, along with other sophisticated applications. With its interactive inspection tools and comprehensive quantification workflows, users can achieve in-depth understanding of material structures and properties. The software offers a suite of post-processing capabilities, including data restructuring, filtering, volume and slice registration, and image stitching. Additionally, it features powerful segmentation tools that enable precise labeling of image characteristics. Dragonfly also addresses image enhancement and segmentation challenges with its advanced Deep Learning solutions. Users are empowered to streamline their 3D analysis processes through easily created macros. By integrating Deep Learning into its functionalities, Dragonfly transforms the landscape of image processing, providing access to the only commercially-supported Deep Learning engine that allows for the training and execution of custom networks, which significantly enhances the overall user experience. This innovative approach ensures that both novice and experienced users can tackle complex imaging tasks with confidence and efficiency.

Invivo™ 6, developed by Anatomage, represents cutting-edge 3D imaging software utilizing Cone Beam CT technology, specifically crafted for dental experts. This innovative platform is ideal for a variety of applications, including implant planning, orthodontics, oral surgery, and restorative dentistry, providing sophisticated visualization tools and accurate treatment planning capabilities. Notable functionalities consist of virtual design options for crowns, abutments, and implants, as well as the integration of digital impressions and the creation of surgical guides. Additionally, the software improves clinical workflows through seamless collaboration and sharing features on the Anatomage cloud, which leads to quicker and more precise diagnosis and treatment strategies. Such advancements not only streamline processes for dental professionals but also enhance patient care outcomes significantly.

Hermia represents an advanced, vendor-agnostic molecular imaging software suite that aims to integrate and enhance clinical workflows across various modalities including nuclear medicine, PET/SPECT/CT/MR review, and sophisticated imaging analysis, all while accommodating scanners and DICOM data from any manufacturer, allowing facilities the flexibility to select their hardware and merge several outdated systems into a single platform. This software provides high-performance multimodal image display and analysis, featuring intuitive and customizable workflows that expedite reporting, enhance data visualization, and minimize manual interventions from acquisition through to interpretation, thus enabling swift and precise reviews of studies like PET/CT, SPECT/CT, and PET/MR. Hermia is equipped with an extensive set of tools that includes optimized SPECT reconstruction suitable for a range of procedures and radiopharmaceuticals, alongside a versatile nuclear medicine processing toolkit tailored for disciplines such as osteology, gastroenterology, nephrology, and endocrinology, as well as specialized modules focusing on pneumology that incorporate lung function assessment and SPECT V/Q quantification. With its ability to seamlessly integrate various imaging modalities, Hermia not only improves operational efficiency but also enhances patient care through more accurate diagnostics.

Medis Suite XA serves as our comprehensive solution for X-Ray angiography, built upon over three decades of expertise in cardiovascular image analysis. This all-inclusive package features an array of modules, including a user-friendly viewer and various analyses dedicated to coronary and vascular assessments, enabling detailed anatomical evaluations of arteries. It also encompasses analyses for both left and right ventricles along with integrated reporting capabilities. Among its offerings are advanced analyses for coronary and peripheral vessels (QCA and QVA) as well as left and right ventriculograms (QLV and QRV). A standout feature is the innovative QFR® analysis, which evaluates the functional significance of lesions without requiring adenosine or a pressure wire. Moreover, the suite allows for seamless integration within the healthcare IT infrastructure, ensuring effortless connectivity with the DICOM network, thus enhancing workflow efficiency and patient care. Ultimately, Medis Suite XA represents a significant advancement in the field of cardiovascular imaging.

CryoTrackIMS is a comprehensive software solution tailored for various fields, including molecular biology, cell banking, cellular biology, clinical samples, biorepositories, biobanking, biochemistry, immunology, and protein laboratories, as well as high-throughput screening, quality assurance, IVF labs, and core facilities. Users can effortlessly design any box, plate, or pie layout by choosing from rows and columns or opting for a pie configuration, allowing their custom box to be generated in mere seconds for data input. Efficient inventory management of precious biological samples and specimens is essential for both fundamental research and the biotech industry. Managing extensive collections of diverse samples such as DNA, RNA, plasmids, clones, proteins, peptides, probes, antibodies, enzymes, specimens, tissues, and cell lines can often become a challenging and overwhelming endeavor that results in significant financial costs alongside frustration and wasted time. CryoTrack provides an all-encompassing solution specifically designed for laboratories within universities, clinics, biotechnology firms, and pharmaceutical organizations. This advanced software not only simplifies sample tracking but also significantly enhances lab efficiency and productivity. By streamlining the organization of critical biological materials, CryoTrackIMS empowers researchers to focus more on their experiments and less on administrative burdens.

Our innovative mobile visualization platform, recognized with awards, allows healthcare professionals to work together and make diagnoses while accessing and sharing 2D/3D medical images seamlessly across various devices. With secure data access from any location, there's no need to transfer or duplicate original files. This platform is selected and relied upon by some of the largest and most cutting-edge healthcare institutions globally. Designed by clinicians for their peers, the ResolutionMD enterprise viewer enhances patient care and optimizes workflows through features that comply with HIPAA regulations, alongside robust mobile functionality. With FDA Class II certification and other international accreditations, you can confidently make diagnoses using both mobile and web applications, ensuring high-quality care for patients everywhere. This innovative approach not only improves efficiency but also fosters a collaborative environment among healthcare providers.

Fujifilm's Synapse 3D represents a cutting-edge visualization solution that has been crafted in conjunction with a variety of medical professionals, including radiologists, cardiologists, and surgeons, providing more than 50 applications designed to improve both the accuracy and efficiency of diagnoses. This platform features advanced server-side technology that accommodates both cloud and on-premise hosting, enabling sophisticated image analyses that aid in interpretation, reporting, and treatment planning while promoting effective clinical collaboration throughout the organization. It addresses specialty fields such as cardiology, pulmonology, oncology, urology, neurology, and gastroenterology, showcasing its versatility. The architecture of Synapse 3D is scalable, allowing for unlimited expansion, and its reliable workflows boost overall productivity while catering to extensive visualization requirements through specialized applications. The platform also includes native cardiology features that enhance cardiac care, and its AI-driven detection capabilities significantly enhance the accuracy and efficiency of interpretations. Additionally, Synapse 3D offers seamless integration with Fujifilm's Synapse Enterprise PACS, making it an invaluable resource for healthcare providers seeking to optimize patient outcomes. With these comprehensive features, it stands to revolutionize the way medical imaging is approached in clinical settings.

Advanced Imaging Concepts (AIC) is at the forefront of delivering top-notch Digital Imaging solutions for Optical Microscopes available today. Are you in the process of acquiring Digital Imaging Equipment for Microscopy but feeling overwhelmed by the options? Let AIC demonstrate the benefits of leveraging your current equipment! Instead of discarding outdated devices, AIC can guide you in integrating advanced features such as Z-Focus control, motorized X-Y stages, and shutters for both transmitted and fluorescent illumination, in addition to deconvolution software and comprehensive Real Time Confocal Systems. Since 1989, AIC has been committed to offering cutting-edge Digital Imaging Solutions to its clientele. Notably, in 1993, AIC launched Image Central™—an innovative MS-Windows program tailored for the microscopy sector that enables effective image archival and databasing. This software serves as a robust information and image management tool, allowing organizations to store, browse, and search for images of all kinds through intuitive alphanumeric queries, ultimately enhancing productivity and efficiency in microscopy research. With AIC by your side, you can maximize the potential of your microscopy investments.

The FDA-cleared D2P® software, in combination with 3D Systems printers, empowers surgeons, radiologists, lab technicians, and device designers to efficiently generate high-quality diagnostic digital 3D models and tangible 3D prints. By importing DICOM images into the D2P standalone modular software, all necessary steps for 3D model segmentation and preparation are streamlined into a single workstation. Designed as a medical device, D2P facilitates pre-operative surgical planning and the creation of 3D-printed anatomical models for diagnostic use. Its distinctive image segmentation toolkit, paired with sophisticated virtual reality (VR) visualization, significantly reduces the time and effort required for clinicians and point-of-care (POC) personnel to produce customized anatomical models for their patients. Furthermore, the digital models generated by D2P can be utilized across various platforms, including 3D printers, VR systems, surgical planning applications, and CAD software, enhancing the overall flexibility and effectiveness of medical practices. This innovative approach not only improves surgical preparation but also fosters collaboration among healthcare professionals by providing them with precise and accessible anatomical representations.

Accelerating the speed, precision, and affordability of cancer diagnoses is crucial, especially considering that one in three individuals will face this disease in their lifetime. Unfortunately, the current diagnostic process is often hindered by slow and costly methods, primarily due to the lack of advanced automated tools that support healthcare professionals. Qritive addresses this challenge by offering an AI-driven solution designed to assist physicians in analyzing both microscopy images and textual patient data efficiently. This innovation not only enhances the effectiveness of hospitals in diagnosing cancer but also contributes to significant cost savings. Additionally, Pantheon serves as a CE-marked, vendor-agnostic digital pathology platform that facilitates the complete digitization of pathology lab workflows and telepathology. It also supports comprehensive report generation and offers a robust platform for AI-driven analysis of whole-slide images in pathology. This technology is particularly adept at distinguishing between a variety of benign conditions and malignant diseases within breast tissue, which is vital for timely and accurate treatment. In doing so, it plays a pivotal role in transforming the landscape of cancer diagnostics.

Realize Medical's Elucis is an FDA-approved extended reality platform that simplifies the segmentation of images, promotes collaboration among remote teams, and allows for procedural planning in a virtual reality space. Elucis is capable of handling an unlimited number of 3D and 4D CT and MR images, ensuring thorough project integration. It boasts cutting-edge image processing features, including both manual and automatic registration, as well as the display of images in 2D, 3D, and 4D formats. The platform’s segmentation tools are engineered for efficiency and user-friendliness, enabling precise measurement, cutting, and planning tasks directly in a virtual environment. Additionally, Elucis includes advanced 4D modeling capabilities that permit intricate segmentation of cardiac structures in mere minutes, regardless of the phase. Users have the flexibility to import 3D structure files from external sources and can easily export their work with a single click. Furthermore, the platform enhances teamwork by allowing multiple users to connect seamlessly with local or remote colleagues throughout the entire workflow, making it a versatile tool for medical professionals. This feature not only streamlines communication but also ensures that all stakeholders can contribute effectively to the project.

Effortlessly identify the suitable landing zone for the treatment of abdominal aneurysms (EVAR), thoracic aneurysms (TEVAR), or the insertion of fenestrated stents (FEVAR). All necessary metrics, including diameter, clock position, volume, and length, can be accurately acquired through automatically detected centerlines or 3D double oblique imaging. Furthermore, integrated manufacturer stent order sheets can create PDF files, simplifying the process of ordering specific stents via email. Our ongoing mission is to enhance the quality and efficiency of cardiovascular image analysis, which in turn optimizes patient treatment outcomes. We strive to align our product offerings with the most recent advancements in the cardiovascular sector. By doing so, we ensure that our customers receive the best software solutions at the most opportune moments. Recognizing the significance of proper training and support, we are committed to making sure all users are proficient and comfortable with their analysis. To meet diverse needs, we provide customizable training options that adapt to individual requirements, fostering a supportive learning environment for all users.

MiNNOVAA is a company specializing in medical information technology, particularly in the realms of medical imaging software and the exchange of medical images. With the guiding principle of "medical imaging innovation," we stand out for our nimbleness and the state-of-the-art technology we utilize in crafting our solutions. Our main areas of concentration are the development of medical image viewers, enhancement of radiology workflows, and the incorporation of artificial intelligence in diagnostic reporting. Our energetic team comprises around 20 skilled programmers and product managers, alongside professionals in marketing, sales, technical support, call center operations, and administration, all dedicated to driving a meaningful transformation in the field of medical imaging and enhancing individual healthcare experiences. We offer a comprehensive clinical imaging IT solution tailored for mid-sized hospitals and imaging clinics, featuring a wide array of functionalities such as on-premise core PACS software, a DICOM web viewer, multi-platform imaging workstation software, seamless integration with EHR/EMR/HIS systems, and an efficient workflow engine/RIS. Ultimately, our commitment to innovation and comprehensive solutions aims to redefine how medical imaging is approached and utilized within healthcare settings.

Fovia Ai's F.A.S.T. aiCockpit serves as an AI viewer that enhances navigation, visualization, and interaction with AI-generated results from various vendors and algorithms through a unified user experience that minimizes the number of clicks needed. This platform facilitates the visualization and interaction of all algorithm outcomes within a single, user-friendly interface, significantly improving the workflow for radiologists and clinical professionals. By providing physician-validated insights to AI orchestrators, PACS, and reporting systems, it adheres to the most up-to-date interoperability standards. The system is compatible with multiple AI formats, such as DICOM Structured Reports, DICOM Key Images, DICOM GSPS, and DICOM segmentation objects. Furthermore, F.A.S.T. aiCockpit boasts a cloud-ready architecture, enabling access to AI-assisted radiology results from anywhere at any time via any web-enabled browser. With just one straightforward integration, users can seamlessly complete their AI capabilities without the need to switch between various viewers, thus streamlining their overall workflow even further. This innovative approach not only enhances efficiency but also empowers healthcare professionals to make more informed decisions quickly.

Mantarray revolutionizes the early phases of preclinical drug testing by integrating functional data with advanced technologies. By enabling simultaneous analysis of 3D engineered muscle tissues that exhibit adult-like functional characteristics, Mantarray facilitates the identification, safety assessment, and effectiveness evaluation of new therapeutics. With an impressive tissue formation success rate exceeding 95%, the Mantarray Plate Kit ensures consistent and reproducible engineered tissues across 24 wells. This innovative platform offers a user-friendly, scalable, and adaptable solution that empowers researchers to analyze 3D tissues in vitro right within their labs. Early adopters can take advantage of this groundbreaking instrument. The Mantarray system employs a unique magnetic sensing method that accurately detects the contractions of engineered muscle tissues (EMTs), allowing users to assess the contractility of 24 tissues simultaneously and in real time, greatly enhancing throughput. Moreover, the accompanying software simplifies the process by eliminating the need for manual contractility calculations, thus streamlining the research workflow. Overall, Mantarray not only improves the efficiency of drug discovery but also enhances the reliability of data obtained during preclinical studies.

MIDAS FEA NX is an advanced finite element analysis (FEA) software designed specifically for intricate structural and civil engineering simulations, featuring an intuitive, CAD-like interface that enhances user experience alongside powerful analytical functions. The software enables engineers to easily import a variety of 3D CAD files and generate high-quality finite element meshes using both automatic and hybrid mesh techniques, thereby minimizing the time spent on manual preparation and enhancing the precision of models. With support for both linear and nonlinear analyses, it can conduct complex simulations utilizing high-performance solvers and parallel computing, making it adept at managing extensive, real-world projects with ease. MIDAS FEA NX is particularly proficient at executing refined method analyses that meet the stringent requirements of design codes for structures characterized by intricate geometries, allowing for comprehensive assessments of stress, deformation, and performance across a range of loading scenarios. Additionally, it offers seamless integration with other tools in the MIDAS COLLECTION and various structural analysis applications, ensuring a cohesive workflow for engineers. Ultimately, the robust feature set of MIDAS FEA NX positions it as a critical resource in the toolkit of any structural engineer.

The EMR Manager serves as the global solution for managing images and documents within Enterprise Electronic Medical Records, catering to the needs of various institutes and departments. It provides a centralized repository for all types of medical and non-medical data, stored as DICOM objects accessible to authorized personnel. Coupled with VEPris, it ensures that even the most intricate workflows are executed efficiently and securely. Healthcare providers can easily access the VEPRO DICOM archive, allowing both referring and post-treatment physicians to view essential images and reports. Patients' multimedia information—including images, films, audio, and text—can be retrieved and displayed in mere seconds, with users having the capability to perform advanced image processing. The EMR Manager comes in three distinct versions, each offering different functionalities. Furthermore, whether in a hospital setting, private practice, or at home, the EMR Manager, along with WEBstudio, enables seamless processing of 3D reconstructions like MIP, MPR, and VR. This versatility enhances collaboration and improves patient care significantly.

VolView is an open-source tool designed for radiological professionals, enabling them to visualize DICOM data in three dimensions through interactive cinematic volume rendering. This application runs directly in web browsers, allowing secure data handling as files remain on the user's device without requiring installation. Supporting a convenient drag-and-drop interface for DICOM files, VolView excels in delivering high-quality and interactive 3D renderings. Users can explore various color presets, modify lighting and transparency settings, crop images, and engage with 3D data for enhanced understanding. The platform features both standard 2D and 3D controls, measurement tools, and annotation capabilities, with continual updates made in response to user suggestions. As it operates locally, VolView harnesses the processing power of the user's CPU, GPU, and disk space, avoiding reliance on external servers or cloud services. Additionally, being open-source, it remains freely available to healthcare professionals, promoting wide accessibility and collaboration in the clinical community. This empowers clinicians to utilize advanced visualization techniques in their diagnostic processes.